Madurai Lok Sabha constituency and Alloy: Difference between pages
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[[Image:Steel wire rope.png|thumb|[[Steel]] is a metal alloy whose major component is [[iron]], with [[carbon]] content between 0.02% and 1.7% by mass.]] |
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'''[[Madurai]]''' is a [[Lok Sabha]] constituency in [[Tamil Nadu]]. |
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{{otheruses4|the material|the specification language|Alloy (specification language)}} |
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===Members of Parliament=== |
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*[[1951]]: [[P.M. Kakkan]], [[Indian National Congress]] |
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*[[1951]]: [[S. Balasubramaniam]], [[Indian National Congress]] |
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*[[1957]]: [[K.T.K. Thangamani]], [[Communist Party of India]] |
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*[[1962]]: [[N.M.R. Subbaraman]], [[Indian National Congress]] |
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*[[1967]]: [[P. Ramamurti]], [[Communist Party of India (Marxist)]] |
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*[[1971]]: [[R.V. Swaminathan]], [[Indian National Congress]] |
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*[[1977]]: [[R.V. Swaminathan]], [[Indian National Congress]] |
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*[[1980]]: [[A.G. Subburaman]], [[Indian National Congress (I)]] |
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*[[1984]]: [[A.G. Subburaman]], [[Indian National Congress]] |
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*[[1989]]: [[A.G.S. Ram Babu]], [[Indian National Congress]] |
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*[[1991]]: [[A.G.S. Ram Babu]], [[Indian National Congress]] |
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*[[1996]]: [[A.G.S. Ram Babu]], [[Tamil Maanila Congress (Moopanar)]] |
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*[[1998]]: [[Subramanian Swamy]], [[Janata Party]] |
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*[[1999]]: [[P. Mohan]], [[Communist Party of India (Marxist)]] |
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*[[2004]]: [[P. Mohan]], [[Communist Party of India (Marxist)]] |
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An '''alloy''' is a [[solid solution]] or [[homogeneous]] mixture of two or more [[chemical element|elements]], at least one of which is a [[metal]], which itself has [[metallic]] properties. It usually has different properties from those of its component elements. |
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==References== |
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[[Election Commission of India]] -http://www.eci.gov.in/StatisticalReports/ElectionStatistics.asp |
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Alloying one metal with others often enhances its properties. |
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For instance, [[steel]] is stronger than [[iron]], its primary element. The physical properties, such as [[density]], [[reactivity]], [[Young's modulus]], and [[electrical conductivity|electrical]] and [[thermal conductivity]], of an alloy may not differ greatly from those of its elements, but engineering properties, such as [[tensile strength]]<ref>Adelbert Phillo Mills, (1922) ''Materials of Construction: Their Manufacture and Properties'', John Wiley & sons, inc, 489 pages, originally published by the University of Wisconsin, Madison</ref> and [[shear strength]] may be substantially different from those of the constituent materials. This is sometimes due to the sizes of the [[atom]]s in the alloy, since larger atoms exert a compressive force on neighboring atoms, and smaller atoms exert a tensile force on their neighbors, helping the alloy resist deformation. Alloys may exhibit marked differences in behavior even when small amounts of one element occur. For example, impurities in semi-conducting [[ferromagnetic]] alloys lead to different properties, as first predicted by White, Hogan, Suhl, Tian Abrie and Nakamura.<ref>[http://prola.aps.org/abstract/PR/v188/i2/p870_1 C. Michael Hogan, (1969) ''Density of States of an Insulating Ferromagnetic Alloy'' Phys. Rev. 188, 870 - 874, [Issue 2 – December 1969]</ref><ref>[http://prola.aps.org/abstract/PRA/v32/i4/p2530_1. X. Y. Zhang and H. Suhl (1985) Phys. Rev. A 32, 2530 - 2533 (1985) [Issue 4 – October 1985]</ref> |
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Some alloys are made by melting and mixing two or more metals. [[Brass]] is an alloy made from copper and zinc. [[Bronze]], used for [[bearing (mechanical)|bearings]], [[statue]]s, [[ornament (architecture)|ornaments]] and [[church bell]]s, is an alloy of [[tin]] and [[copper]]. |
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Unlike pure metals, most alloys do not have a single [[melting point]]. Instead, they have a melting range in which the material is a mixture of [[solid]] and [[liquid]] phases. The temperature at which melting begins is called the [[solidus (chemistry)|solidus]] and the temperature when melting is complete is called the [[liquidus]]. However, for most alloys there is a particular proportion of constituents which give them a single melting point or (rarely) two. This is called the alloy's [[eutectic]] mixture. |
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==Classification== |
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Alloys can be classified by the number of their constituents. An alloy with two components is called a '''binary alloy'''; one with three is a '''ternary alloy''', and so forth. Alloys can be further classified as either '''substitution alloys''' or '''interstitial alloys''', depending on their method of formation. In substitution alloys, the atoms of the components are approximately the same size and the various atoms are simply substituted for one another in the crystal structure. An example of a (binary) substitution alloy is [[brass]], made up of [[copper]] and [[zinc]]. Interstitial alloys occur when the atoms of one component are substantially smaller than the other and the smaller atoms fit into the spaces (interstices) between the larger atoms. |
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if you mix poo with an alloy it turns to gold |
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==Terminology== |
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In practice, some alloys are used so predominantly with respect to their base metals that the name of the primary constituent is also used as the name of the alloy. For example, 14 [[Carat (purity)|carat]] [[gold]] is an alloy of gold with other elements. Similarly, the [[silver]] used in [[jewelry]] and the [[aluminium]] used as a structural building material are also alloys. |
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The term "alloy" is sometime used in everyday speech as a synonym for a particular alloy. For example, automobile wheels made of [[aluminium alloy]] are commonly referred to as simply "alloy wheels". The usage is obviously indefinite, since steels and most other metals in practical use are also alloys. |
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==See also== |
==See also== |
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{{Wiktionarypar|alloy}} |
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* [[Madurai]] |
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* [[List of Constituencies of the Lok Sabha]] |
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* [[List of alloys]] |
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* [[Intermetallics]] |
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* [[Heat treatment]] |
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* [[CALPHAD (method)]] |
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==References== |
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{{reflist}} |
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==External links== |
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* [http://www.uni-ulm.de/~hhoster/personal/surface_alloys.html Surface alloys] |
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[[Category:Alloys|*]] |
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{{Template:Lok Sabha constituencies of Tamil Nadu}} |
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[[Category: |
[[Category:Metallurgy]] |
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[[mr:मदुरै (लोकसभा मतदारसंघ)]] |
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[[zh-yue:合金]] |
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[[pt:Liga metálica]] |
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[[ro:Aliaj]] |
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[[fi:Metalliseos]] |
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[[ta:கலப்புலோகம்]] |
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[[th:โลหะผสม]] |
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[[vi:Hợp kim]] |
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[[tr:Alaşım]] |
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[[uk:Сплави]] |
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[[yi:געמיש מעטאלען]] |
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[[kn:ಮಿಶ್ರ ಲೋಹ]] |
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Revision as of 20:04, 12 October 2008
An alloy is a solid solution or homogeneous mixture of two or more elements, at least one of which is a metal, which itself has metallic properties. It usually has different properties from those of its component elements.
Alloying one metal with others often enhances its properties. For instance, steel is stronger than iron, its primary element. The physical properties, such as density, reactivity, Young's modulus, and electrical and thermal conductivity, of an alloy may not differ greatly from those of its elements, but engineering properties, such as tensile strength[1] and shear strength may be substantially different from those of the constituent materials. This is sometimes due to the sizes of the atoms in the alloy, since larger atoms exert a compressive force on neighboring atoms, and smaller atoms exert a tensile force on their neighbors, helping the alloy resist deformation. Alloys may exhibit marked differences in behavior even when small amounts of one element occur. For example, impurities in semi-conducting ferromagnetic alloys lead to different properties, as first predicted by White, Hogan, Suhl, Tian Abrie and Nakamura.[2][3] Some alloys are made by melting and mixing two or more metals. Brass is an alloy made from copper and zinc. Bronze, used for bearings, statues, ornaments and church bells, is an alloy of tin and copper.
Unlike pure metals, most alloys do not have a single melting point. Instead, they have a melting range in which the material is a mixture of solid and liquid phases. The temperature at which melting begins is called the solidus and the temperature when melting is complete is called the liquidus. However, for most alloys there is a particular proportion of constituents which give them a single melting point or (rarely) two. This is called the alloy's eutectic mixture.
Classification
Alloys can be classified by the number of their constituents. An alloy with two components is called a binary alloy; one with three is a ternary alloy, and so forth. Alloys can be further classified as either substitution alloys or interstitial alloys, depending on their method of formation. In substitution alloys, the atoms of the components are approximately the same size and the various atoms are simply substituted for one another in the crystal structure. An example of a (binary) substitution alloy is brass, made up of copper and zinc. Interstitial alloys occur when the atoms of one component are substantially smaller than the other and the smaller atoms fit into the spaces (interstices) between the larger atoms.
if you mix poo with an alloy it turns to gold
Terminology
In practice, some alloys are used so predominantly with respect to their base metals that the name of the primary constituent is also used as the name of the alloy. For example, 14 carat gold is an alloy of gold with other elements. Similarly, the silver used in jewelry and the aluminium used as a structural building material are also alloys.
The term "alloy" is sometime used in everyday speech as a synonym for a particular alloy. For example, automobile wheels made of aluminium alloy are commonly referred to as simply "alloy wheels". The usage is obviously indefinite, since steels and most other metals in practical use are also alloys.
See also
References
- ^ Adelbert Phillo Mills, (1922) Materials of Construction: Their Manufacture and Properties, John Wiley & sons, inc, 489 pages, originally published by the University of Wisconsin, Madison
- ^ C. Michael Hogan, (1969) Density of States of an Insulating Ferromagnetic Alloy Phys. Rev. 188, 870 - 874, [Issue 2 – December 1969
- ^ X. Y. Zhang and H. Suhl (1985) Phys. Rev. A 32, 2530 - 2533 (1985) [Issue 4 – October 1985